Genome-wide mapping with biallelic markers in Arabidopsis thaliana.

Single-nucleotide polymorphisms, as well as small insertions and deletions (here referred to collectively as simple nucleotide polymorphisms, or SNPs), comprise the largest set of sequence variants in most organisms. Positional cloning based on SNPs may accelerate the identification of human disease traits and a range of biologically informative mutations. The recent application of high-density oligonucleotide arrays to allele identification has made it feasible to genotype thousands of biallelic SNPs in a single experiment. It has yet to be established, however, whether SNP detection using oligonucleotide arrays can be used to accelerate the mapping of traits in diploid genomes. The cruciferous weed Arabidopsis thaliana is an attractive model system for the construction and use of biallelic SNP maps. Although important biological processes ranging from fertilization and cell fate determination to disease resistance have been modelled in A. thaliana, identifying mutations in this organism has been impeded by the lack of a high-density genetic map consisting of easily genotyped DNA markers. We report here the construction of a biallelic genetic map in A. thaliana with a resolution of 3.5 cM and its use in mapping Eds16, a gene involved in the defence response to the fungal pathogen Erysiphe orontii. Mapping of this trait involved the high-throughput generation of meiotic maps of F2 individuals using high-density oligonucleotide probe array-based genotyping. We developed a software package called InterMap and used it to automatically delimit Eds16 to a 7-cM interval on chromosome 1. These results are the first demonstration of biallelic mapping in diploid genomes and establish means for generalizing SNP-based maps to virtually any genetic organism.

Transcription interferes with elements important for chromosome maintenance in Saccharomyces cerevisiae.

Transcription directed into a Saccharomyces cerevisiae autonomously replicating sequence (ARS) causes high-frequency loss of minichromosomes. Conditionally stable artificial yeast chromosomes were constructed that contain an inducible GAL promoter upstream of ARS1. Under growth conditions in which the promoter was inactive, these chromosomes were mitotically stable; however, when the GAL promoter was induced, the chromosomes became extremely unstable as a result of transcriptional impairment of ARS function. This interference by the GAL promoter occurred only in cis but can occur from either side of ARS1. Transcriptional interference of ARS function can be monitored readily by using a visual colony-color assay (P. Hieter, C. Mann, M. Snyder, and R.W. Davis, Cell 40:381-392, 1985), which was further developed as a sensitive in vivo assay for sequences which rescue ARS from transcription. DNA fragments from the 3' ends of genes, inserted downstream of the GAL promoter, protected ARS function from transcriptional interference. This assay is expected to be independent of both RNA transcript stability and processing. Philippsen et al. have shown that transcription into a yeast centromere inhibits CEN function in vivo (L. Panzeri, I. Groth-Clausen, J. Shepard, A. Stotz, and P. Philippsen, Chromosomes Today 8:46-58, 1984). We identified two 200- to 300-base-pair DNA fragments flanking CEN4 that rescued ARS1 from transcription. Both of these fragments protected ARS from transcription when inserted in either orientation. The 3' ends of stable transcripts are encoded by fragments that protected the ARS from transcription, suggesting that the protection was achieved by transcription termination. It is suggested that protection of elements important for the replication and segregation of eucaryotic chromosomes from transcription is necessary for their proper function in vivo.

Mapping genomic library clones using oligonucleotide arrays.

We have developed a high-density DNA probe array and accompanying biochemical and informatic methods to order clones from genomic libraries. This approach involves a series of enzymatic steps for capturing a set of short dispersed sequence markers scattered throughout a high-molecular-weight DNA. By this process, all the ambiguous sequences lying adjacent to a given Type IIS restriction site are ligated between two DNA adapters. These markers, once amplified and labeled by PCR, can be hybridized and detected on a high-density oligonucleotide array bearing probes complementary to all possible markers. The array is synthesized using light-directed combinatorial chemistry. For each clone in a genomic library, a characteristic set of sequence markers can be determined. On the basis of the similarity between the marker sets for each pair of clones, their relative overlap can be measured. The library can be sequentially ordered into a contig map using this overlap information. This new methodology does not require gel-based methods or prior sequence information and involves manipulations that should allow for easy adaptation to automated processing and data collection.

A comparative analysis of distinctive features of yeast protein sequences.

The recently published sequence of yeast chromosome III (YCIII) provides the longest continuous stretch of a eukaryotic DNA molecule sequenced to date (315 kb). The sequence contains 116 distinct AUG-initiated open reading frames of at least 200 codons in length, more than 50 of which had not been described previously nor bear significant similarity to known proteins. We have analysed the YCIII known and putative protein sequences with respect to significant statistical features which might reflect on structural and functional characteristics. The YCIII proteins have striking similarities and differences in their sequence attribute distributions compared to the corresponding distributions for all available yeast sequences and other protein collections. Nine examples of YCIII proteins with distinctive sequence features are discussed in detail.

Assessments of DNA inhomogeneities in yeast chromosome III.

With the sequencing of the first complete eukaryotic chromosome, III of yeast (YCIII) of length 315 kb, several types of questions concerning chromosomal organization and the heterogeneity of eukaryotic DNA sequences can be approached. We have undertaken extensive analysis of YCIII with the goals of: (1) discerning patterns and anomalies in the occurrences of short oligonucleotides; (2) characterizing the nature and locations of significant direct and inverted repeats; (3) delimiting regions unusually rich in particular base types (e.g., G+C, purines); and (4) analyzing the distributions of markers of interest, e.g., delta (delta) elements, ARS (autonomous replicating sequences), special oligonucleotides, close repeats and close dyad pairings, and gene sequences. YCIII reveals several distinctive sequence features, including: (i) a relative abundance of significant local and global repeats highlighting five genes containing substantial close or tandem DNA repeats; (ii) an anomalous distribution of delta elements involving two clusters and a long gap; (iii) a significantly even distribution of ARS; (iv) a relative increase in the frequency of T runs and AT iterations downstream of genes and A runs upstream of genes; and (v) two regions of complex repetitive sequences and anomalous DNA composition, 29000-31000 and 291000-295000, the latter centered at the HMRa locus. Interpretations of these findings for chromosomal organization and implications for regulation of gene expression are discussed.

High-throughput polymorphism screening and genotyping with high-density oligonucleotide arrays.

A highly reliable and efficient technology has been developed for high-throughput DNA polymorphism screening and large-scale genotyping. Photolithographic synthesis has been used to generate miniaturized, high-density oligonucleotide arrays. Dedicated instrumentation and software have been developed for array hybridization, fluorescent detection, and data acquisition and analysis. Specific oligonucleotide probe arrays have been designed to rapidly screen human STSs, known genes and full-length cDNAs. This has led to the identification of several thousand biallelic single-nucleotide polymorphisms (SNPs). Meanwhile, a rapid and robust method has been developed for genotyping these SNPs using oligonucleotide arrays. Each allele of an SNP marker is represented on the array by a set of perfect match and mismatch probes. Prototype genotyping chips have been produced to detect 400, 600 and 3000 of these SNPs. Based on the preliminary results, using oligonucleotide arrays to genotype several thousand polymorphic loci simultaneously appears feasible.